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Lecture Presentation. Chapter 16 Aqueous Ionic Equilibrium. chengkuan@mail.ntou.edu.tw. Aqueous Ionic Equilibrium. 16.1 The Danger of Antifreeze 16.2 Buffers: Solution That Resist pH Change 16.3 Buffer Effectiveness: Buffer Range and Capacity 16.4 Titration and pH Curve
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Lecture Presentation Chapter 16Aqueous Ionic Equilibrium chengkuan@mail.ntou.edu.tw
Aqueous Ionic Equilibrium 16.1 The Danger of Antifreeze 16.2 Buffers: Solution That Resist pH Change 16.3 Buffer Effectiveness: Buffer Range and Capacity 16.4 Titration and pH Curve 16.5 Solubility Equilibria and the Solubility Product Constant 16.6 Precipitation 16.7 Qualitative Chemical Analysis 16.8 Complex Ion Equilibria
The Danger of Antifreeze • Each year, thousands of pets and wildlife species die from consuming antifreeze. • Most brands of antifreeze contain ethylene glycol. • Sweet taste • Initial effect drunkenness • Metabolized in the liver to glycolic acid • HOCH2COOH
Why Is Glycolic Acid Toxic? • In high enough concentration in the bloodstream, glycolic acid overwhelms the buffering ability of the HCO3− in the blood, causing the blood pH to drop. • Low blood pH compromises its ability to carry O2. • Acidosis • One treatment is to give the patient ethyl alcohol, which has a higher affinity for the enzyme that catalyzes the metabolism of ethylene glycol.
Buffer Solutions • Resist changes in pH when an acid or base is added. • Act by neutralizing acid or base that is added to the buffered solution. • Contain either • Significant amounts of a weak acid and its conjugate base • Significant amounts of a weak base and its conjugate acid • Blood has a mixture of H2CO3 and HCO3−
Making an Acidic Buffer Solution It must contain significant amounts of both a weak acid and its conjugate base.
Basic BuffersB:(aq) + H2O(l) H:B+(aq) + OH−(aq) • Buffers can also be made by mixing a weak base, (B:), with a soluble salt of its conjugate acid, H:B+Cl− H2O(l) + NH3(aq) NH4+(aq) + OH−(aq)
An Acidic Buffer Solution • If a strong base is added, it is neutralized by the weak acid (HC2H3O2) in the buffer. NaOH(aq) + HC2H3O2(aq) H2O(l) + NaC2H3O2(aq) • If the amount of NaOH added is less than the amount of acetic acid present, the pH change is small. • If a strong acid is added, it is neutralized by the conjugate base (NaC2H3O2) in the buffer. HCl(aq) + NaC2H3O2 HC2H3O2(aq) + NaCl(aq) • If the amount of HCl is less than the amount of NaC2H3O2 present, the pH change is small.
How Acid Buffers Work: Addition of Base HA(aq) + H2O(l) A−(aq) + H3O+(aq) • Buffers work by applying Le Châtelier’s principle to weak acid equilibrium. • Buffer solutions contain significant amounts of the weak acid molecules, HA . • These molecules react with added base to neutralize it. HA(aq) + OH−(aq) → A−(aq) + H2O(l)
Action of a Buffer Figure 16.3 pg 762
How Acid Buffers Work: Addition of AcidHA(aq) + H2O(l) A−(aq) + H3O+(aq) • The buffer solution also contains significant amounts of the conjugate base anion, A−. • These ions combine with added acid to make more HA. H+(aq) + A−(aq) → HA(aq) • After the equilibrium shifts, the concentration of H3O+ is kept constant.
Common Ion EffectHA(aq) + H2O(l) A−(aq) + H3O+(aq) • Adding a salt containing the anion NaA, which is the conjugate base of the acid (the common ion), shifts the position of equilibrium to the left. • This causes the pH to be higher than the pH of the acid solution, lowering the H3O+ ion concentration.
Example 16.1Calculating the pH of a Buffer Solution Calculate the pH of a buffer solution that is 0.100 M in HC2H3O2 and 0.100 M in NaC2H3O2 Solution 1. Write the balanced equation for the ionization of the acid and use it as a guide to prepare an ICE table showing the given concentrations of the acid and its conjugate base as the initial concentrations. Leave room in the table for the changes in concentrations and for the equilibrium concentrations. 2. Represent the change in the concentration of H3O+ with the variable x. Express the changes in the concentrations of the other reactants and products in terms of x.
Example 16.1Calculating the pH of a Buffer Solution Continued 3. Sum each column to determine the equilibrium concentrations in terms of the initial concentrations and the variable x. 4. Substitute the expressions for the equilibrium concentrations (from step 3) into the expression for the acid ionization constant. In most cases, you can make the approximation that x is small. (See Sections 14.8 and 15.6 to review the x is small approximation.)
Example 16.1Calculating the pH of a Buffer Solution Continued Substitute the value of the acid ionization constant (from Table 15.5) into the Ka expression and solve for x. Confirm that x is small by calculating the ratio of x and the number it was subtracted from in the approximation. The ratio should be less than 0.05 (or 5%). Therefore the approximation is valid. 5. Determine the H3O+ concentration from the calculated value of x and substitute into the pH equation to find pH.
Henderson–Hasselbalch Equation • An equation derived from the Ka expression that allows us to calculate the pH of a buffer solution. • The equation calculates the pH of a buffer from the pKa and initial concentrations of the weak acid and salt of the conjugate base, as long as the “x is small” approximation is valid.
Deriving the Henderson–Hasselbalch Equation Consider the equilibrium expression for a generic acidic buffer: Solving for H3O+ we have the following:
Deriving the Henderson–Hasselbalch Equation –log[H3O+] = –logKa + log([A–]/[HA) Since pH = –log[H3O+] and pKa = –logKa pH = pKa + log([A–]/[HA)
Example 16.2Calculating the pH of a Buffer Solution as an Equilibrium Problem and with the Henderson–Hasselbalch Equation Calculate the pH of a buffer solution that is 0.050 M in benzoic acid (HC7H5O2) and 0.150 M in sodium benzoate (NaC7H5O2). For benzoic acid, Ka = 6.5 × 10–5. Solution Equilibrium Approach Write the balanced equation for the ionization of the acid and use it as a guide to prepare an ICE table. Substitute the expressions for the equilibrium concentrations into the expression for the acid ionization constant. Make the x is small approximation and solve for x.
Example 16.2Calculating the pH of a Buffer Solution as an Equilibrium Problem and with the Henderson–Hasselbalch Equation Continued Since [H3O+] = x, we calculate pH as follows: Confirm that the x is small approximation is valid by calculating the ratio of x to the number it was subtracted from in the approximation. The ratio should be less than 0.05 (or 5%). (See Sections 14.8 and 15.6 to review the x is small approximation.) The approximation is valid. Henderson–Hasselbalch Approach To find the pH of this solution, determine which component is the acid and which is the base and substitute their concentrations into the Henderson–Hasselbalch equation to calculate pH.
Example 16.2Calculating the pH of a Buffer Solution as an Equilibrium Problem and with the Henderson–Hasselbalch Equation Continued HC7H5O2 is the acid and NaC7H5O2 is the base. Therefore, we calculate the pH as follows: Confirm that the x is small approximation is valid by calculating the [H3O+] from the pH. Since [H3O+] is formed by ionization of the acid, the calculated [H3O+] has to be less than 0.05 (or 5%) of the initial concentration of the acid in order for the x is small approximation to be valid. The approximation is valid.
Henderson–Hasselbalch Equation for Basic Buffers • The Henderson–Hasselbalch equation is written for a chemical reaction with a weak acid reactant and its conjugate base as a product. • The chemical equation of a basic buffer is written with a weak base as a reactant and its conjugate acid as a product. B: + H2O H:B+ + OH− • To apply the Henderson–Hasselbalch equation, the chemical equation of the basic buffer must be looked at like an acid reaction. H:B+ + H2O B: + H3O+ pKa + pKb = 14
Do I Use the Full Equilibrium Analysis or the Henderson–Hasselbalch Equation? • The Henderson–Hasselbalch equation is generally good enough when the “x is small” approximation is applicable. • Generally, the “x is small” approximation will work when both of the following are true: • The initial concentrations of acid and salt arenot very dilute. • The Ka is fairly small. • For most problems, this means that the initial acid and salt concentrations should be over 100 to 1000 times larger than the value of Ka.
Action of a Buffer Figure 16.3 pg 762
How Much Does the pH of a Buffer Change When an Acid or Base Is Added? • Calculating the new pH after adding acid or base requires breaking the problem into two parts: • A stoichiometry calculation for the reaction of the added chemical with one of the ingredients of the buffer to reduce its initial concentration and increase the concentration of the other. • Added acid reacts with the A− to make more HA • Added base reacts with the HA to make more A− • An equilibrium calculation of [H3O+] using the new initial values of [HA] and [A−]
Example 16.3Calculating the pH Change in a Buffer Solution after the Addition of a Small Amount of Strong Acid or Base A 1.0 L buffer solution contains 0.100 mol HC2H3O2 and 0.100 mol NaC2H3O2. The value of Ka for HC2H3O2 is 1.8 × 10–5. Because the initial amounts of acid and conjugate base are equal, the pH of the buffer is equal to pKa = –log(1.8 × 10–5) = 4.74. Calculate the new pH after adding 0.010 mol of solid NaOH to the buffer. For comparison, calculate the pH after adding 0.010 mol of solid NaOH to 1.0 L of pure water. (Ignore any small changes in volume that might occur upon addition of the base.) Solution Part I: Stoichiometry. The addition of the base converts a stoichiometric amount of acid to the conjugate base (adding base creates more base). Write an equation showing the neutralization reaction and then set up a table to track the changes. Part II: Equilibrium. Write the balanced equation for the ionization of the acid and use it as a guide to prepare an ICE table. Use the amounts of acid and conjugate base from part I as the initial amounts of acid and conjugate base in the ICE table.
Example 16.3Calculating the pH Change in a Buffer Solution after the Addition of a Small Amount of Strong Acid or Base Continued Substitute the expressions for the equilibrium concentrations of acid and conjugate base into the expression for the acid ionization constant. Make the x is small approximation and solve for x. Calculate the pH from the value of x, which is equal to [H3O+].
Example 16.3Calculating the pH Change in a Buffer Solution after the Addition of a Small Amount of Strong Acid or Base Continued Confirm that the x is small approximation is valid by calculating the ratio of x to the smallest number it was subtracted from in the approximation. The ratio should be less than 0.05 (or 5%). The approximation is valid. Part II: Equilibrium Alternative (using the Henderson–Hasselbalch equation). As long as the x is small approximation is valid, you can substitute the quantities of acid and conjugate base after the addition (from part I) into the Henderson–Hasselbalch equation and calculate the new pH.
Example 16.3Calculating the pH Change in a Buffer Solution after the Addition of a Small Amount of Strong Acid or Base Continued The pH of 1.0 L of water after adding 0.010 mol of NaOH is calculated from the [OH–]. For a strong base, [OH–] is simply the number of moles of OH– divided by the number of liters of solution. Check Notice that the buffer solution changed from pH = 4.74 to pH = 4.83 upon addition of the base (a small fraction of a single pH unit). In contrast, the pure water changed from pH = 7.00 to pH = 12.00, five whole pH units (a factor of 105). Notice also that even the buffer solution got slightly more basic upon addition of a base, as we would expect. To check your answer, always make sure the pH goes in the direction you expect: adding base should make the solution more basic (higher pH); adding acid should make the solution more acidic (lower pH).
Buffering Effectiveness • A good buffer should be able to neutralize moderate amounts of added acid or base. • The effectiveness of a buffer depends on two factors (1) the absolute amounts of acid and base, and (2)the relative amounts of acid and base. • The buffering capacityis the amount of acid or base a buffer can neutralize. • The buffering rangeis the pH range the buffer can be effective.
Buffering Capacity A concentrated buffer can neutralize more added acid or base than a dilute buffer. HA(aq) + OH−(aq) → A−(aq) + H2O(l) H+(aq) + A−(aq) → HA(aq)
Buffering Capacity • Buffering capacity is the amount of acid or base that can be added to a buffer without causing a large change in pH. • The buffering capacity increases with increasing absolute concentration of the buffer components.
Effectiveness of Buffers • A buffer will be most effective when the [base]:[acid] = 1. • Equal concentrations of acid and base • A buffer will be effective when 0.1 < [base]:[acid] < 10. • A buffer will be most effective when the [acid] and the [base] are large.
Buffering Range • We have said that a buffer will be effective when 0.1 < [base]:[acid] < 10. Lowest pH Highest pH Therefore, the effective pH range of a buffer is pKa± 1. When choosing an acid to make a buffer, choose one whose pKa is closest to the pH of the buffer.
Example 16.5Preparing a Buffer Which acid would you choose to combine with its sodium salt to make a solution buffered at pH 4.25? For the best choice, calculate the ratio of the conjugate base to the acid required to attain the desired pH. chlorous acid (HClO2) pKa = 1.95 formic acid (HCHO2) pKa = 3.74 nitrous acid (HNO2) pKa = 3.34 hypochlorous acid (HClO) pKa = 7.54 Solution The best choice is formic acid because its pKa lies closest to the desired pH. You can calculate the ratio of conjugate base (CHO2–) to acid (HCHO2) required by using the Henderson–Hasselbalch equation as follows:
Titration • In an acid–base titration, a solution of known concentration (titrant) is slowly added to a solution of unknown concentration from a burette until the reaction is complete. • When the reaction is complete we have reached the endpointof the titration. • An indicator may be added to determine the endpoint. • An indicator is a chemical that changes color when the pH changes. • When the moles of H3O+ = moles of OH−, the titration has reached its equivalence point.
Titration Curve • It is a plot of pH versus the amount of added titrant. • The inflection point of the curve is the equivalence point of the titration. • Prior to the equivalence point, the unknown solution in the flask is in excess, so the pH is closest to its pH. • The pH of the equivalence point depends on the pH of the salt solution. • Equivalence point of neutral salt, pH = 7 • Equivalence point of acidic salt, pH < 7 (NH4+) • Equivalence point of basic salt, pH > 7 (A-) • Beyond the equivalence point, the known solution in the burette is in excess, so the pH approaches its pH.
Titration of a Strong Base with a Strong Acid • If the titration is run so that the acid is in the burette and the base is in the flask, the titration curve will be the reflection of the one just shown.
Example 16.6Strong Acid–Strong Base Titration pH Curve A 50.0 mL sample of 0.200 M sodium hydroxide is titrated with 0.200 M nitric acid. Calculate pH: a. after adding 30.00 mL of HNO3b. at the equivalence point Solution a. Begin by calculating the initial amount of NaOH (in moles) from the volume and molarity of the NaOH solution. Because NaOH is a strong base, it dissociates completely, so the amount of OH– is equal to the amount of NaOH. Calculate the amount of HNO3 (in moles) added at 30.0 mL from the molarity of the HNO3 solution. As HNO3 is added to the solution, it neutralizes some of the OH–. Calculate the number of moles of OH– remaining by setting up a table based on the neutralization reaction that shows the amount of OH– before the addition, the amount of H3O+ added, and the amounts left after the addition.
Example 16.6Strong Acid–Strong Base Titration pH Curve Continued Calculate the OH– concentration by dividing the amount of OH– remaining by the total volume (initial volume plus added volume). Calculate the pOH from [OH–]. Calculate the pH from the pOH using the equation pH + pOH = 14. b. At the equivalence point, the strong base has completely neutralized the strong acid. The [H3O+] at 25 °C from the ionization of water is 1.00 × 10–7 M and the pH is therefore 7.00. pH = 7.00
Titration of a Weak Acid with a Strong Base • Titrating a weak acid with a strong base results in differences in the titration curve at the equivalence point and excess acid region. • The initial pH is determined using the Ka of the weak acid. • The pH in the excess acid region is determined as you would determine the pH of a buffer. • The pH at the equivalence point is determined using the Kb of the conjugate base of the weak acid. • The pH after equivalence is dominated by the excess strong base. • The basicity from the conjugate base anion is negligible.
Titrating Weak Acid with a Strong Base • The initial pH is that of the weak acid solution. • Calculate like a weak acid equilibrium problem • Before the equivalence point, the solution becomes a buffer. • Calculate molHAinit and mol A−init using reaction stoichiometry • Calculate pH with Henderson–Hasselbalch using molHAinit and mol A−init • Half-neutralization pH = pKa
Example 16.7Weak Acid–Strong Base Titration pH Curve A 40.0 mL sample of 0.100 M HNO2 is titrated with 0.200 M KOH. Calculate: a. the volume required to reach the equivalence point b. the pH after adding 5.00 mL of KOH c. the pH at one-half the equivalence point Solution a. The equivalence point occurs when the amount (in moles) of added base equals the amount (in moles) of acid initially in the solution. Begin by calculating the amount (in moles) of acid initially in the solution. The amount (in moles) of KOH that must be added is equal to the amount of the weak acid. Calculate the volume of KOH required from the number of moles of KOH and the molarity.
Example 16.7Weak Acid–Strong Base Titration pH Curve Continued b. Use the concentration of the KOH solution to calculate the amount (in moles) of OH– in 5.00 mL of the solution. Prepare a table showing the amounts of HNO2 and NO2– before and after the addition of 5.00 mL KOH. The addition of the KOH stoichiometrically reduces the concentration of HNO2 and increases the concentration of NO2–. Since the solution now contains significant amounts of a weak acid and its conjugate base, use the Henderson–Hasselbalch equation and pKa for HNO2 (which is 3.34) to calculate the pH of the solution.
Example 16.7Weak Acid–Strong Base Titration pH Curve Continued c. At one-half the equivalence point, the amount of added base is exactly one-half the initial amount of acid. The base converts exactly half of the HNO2 into NO2–, resulting in equal amounts of the weak acid and its conjugate base. The pH is therefore equal to pKa.